Specifics of Al substitution into boron carbide: A DFT study

IF 2.9 Q1 MATERIALS SCIENCE, CERAMICS Open Ceramics Pub Date : 2024-10-10 DOI:10.1016/j.oceram.2024.100695

Oleksandr Vasiliev, Vladyslav Bilyi

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Abstract

Boron carbide (B₄C), known for its hardness and low density, is prone to local amorphization under high non-hydrostatic loads, limiting its applications. Aluminum doping is promising due to aluminum's atomic size, fitting into the B₄C crystal lattice, particularly the intericosahedra chain, potentially reducing amorphization. This work uses first-principles calculations to study aluminum placement in B₄C. We examine the potential for Al substitution in the icosahedron and intericosahedra chain, identifying possible locations. Results show that aluminum can't replace atoms in the icosahedron, but substituting one central atom in the intericosahedra chain with aluminum is energetically favorable and likely changes the chain configuration to an angular one. Additionally, aluminum can substitute one carbon in the (C-B-C) chain of B₁₂(C-B-C) boron carbide. Comparative analysis suggests these configurations may coexist. Our study offers a theoretical model that can guide future experimental efforts and provides valuable insights into the structural specifics of aluminum-doped boron carbide.

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铝取代碳化硼的特异性：DFT 研究

碳化硼（B4C）以硬度高、密度低著称，但在高非静水负载下容易发生局部非晶化，从而限制了其应用。由于铝的原子尺寸与 B4C 晶格（尤其是二十面体链）相匹配，因此掺铝很有前景，有可能减少非晶化。这项研究利用第一原理计算来研究铝在 B4C 中的位置。我们研究了铝在二十面体和二十面体间链中的替代潜力，确定了可能的位置。结果表明，铝不能取代二十面体中的原子，但用铝取代二十面体间链中的一个中心原子在能量上是有利的，并有可能将链构型改变为角构型。此外，铝还可以替代 B12（C-B-C）碳化硼（B12(C-B-C)）链中的一个碳。比较分析表明，这些构型可能共存。我们的研究提供了一个可以指导未来实验工作的理论模型，并为了解掺铝碳化硼的结构特征提供了宝贵的见解。

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